Structure and supercapacitor performance of graphene materials obtained from brominated and fluorinated graphites

Carbon

Volumn 78, Issue , 2014, Pages 137-146

  Bulusheva, L G ^a,b   Tur, V A ^a   Fedorovskaya, E O ^a   Asanov, I P ^a,b   Pontiroli, D ^c   Ricco M ^c   Okotrub, A V ^a,b  

^a NIKOLAEV INSTITUTE OF INORGANIC CHEMISTRY   (Russian Federation)

^b NOVOSIBIRSK STATE UNIVERSITY   (Russian Federation)

^c UNIVERSITY OF PARMA   (Italy)

Author keywords

[No Author keywords available]

Indexed keywords

BROMINE; CAPACITORS; GRAPHENE; GRAPHITE; INFRARED SPECTROSCOPY; MATERIALS TESTING;

ELECTROCHEMICAL TESTING; ELECTRODE MATERIAL; ELECTRODE PREPARATION; FEW-LAYER GRAPHENE; FLUORINATED GRAPHITE; FUNCTIONAL COMPOSITIONS; INTERCALATED GRAPHITE; X-RAY PHOTOELECTRONS;

DISPERSIONS;

EID: 84906320281     PISSN: 00086223     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbon.2014.06.061     Document Type: Article

References (64)

1. Y. Huang, J. Liang, and Y. Chen An overview of the applications of graphene-based materials in supercapacitors Small 8 2012 1805 1834
2. S. Pei, and H.-M. Cheng The reduction of graphene oxide Carbon 50 2012 3210 3228
3. T. Kuila, A.K. Mishra, P. Khanra, N.H. Kim, and J.H. Lee Recent advances in the efficient reduction of graphene oxide and its application as energy storage electrode materials Nanoscale 5 2013 52 71
4. W. Gao, L.B. Alemany, L. Ci, and P.M. Ajayan New insights into the structure and reduction of graphite oxide Nat Chem 1 2009 403 408
5. S. Stankovich, D.A. Dikin, R.D. Piner, K.A. Kohlhaas, A. Kleinhammes, and Y. Jia et al. Synthesis of graphene-based nanosheets via chemical reduction of exfoliated graphite oxide Carbon 45 2007 1558 1565
6. H.A. Becerril, J. Mao, Z. Liu, R.M. Stoltenberg, Z. Bao, and Y. Chen Evaluation of solution-processed reduced graphene oxide films as transparent conductors ACS Nano 2 2008 463 470
7. D. Luo, G. Zhang, J. Liu, and X. Sun Evaluation criteria for reduced graphene oxide J Phys Chem C 115 2011 11327 11335
8. H. Bai, C. Li, and G. Shi Functional composite materials based on chemically converted graphene Adv Mater 23 2011 1089 1115
9. M. Cai, D. Thorpe, D.H. Adamson, and H.C. Schniepp Methods of graphite exfoliation J Mater Chem 22 2012 24992 25002
10. Z. Lin, Y. Liu, Y. Yao, O.J. Hildreth, Z. Li, and K. Moon et al. Superior capacitance of functionalized graphene J Phys Chem C 115 2011 7120 7125
11. X. Du, H. Song, and X. Chen Relationship between intrinsic capacitance and thickness of graphene nanosheets J Mater Chem 22 2012 13091 13096
12. M.M. Hantel, T. Kaspar, R. Nesper, A. Wokaun, and R. Kötz Partially reduced graphite oxide for supercapacitor electrodes: effect of graphene layer spacing and huge specific capacitance Electrochem Commun 13 2011 90 92
13. Y. Wang, Y. Wu, Y. Huang, F. Zhang, X. Yang, and Y. Ma et al. Preventing graphene sheets from restacking for high capacitance performance J Phys Chem C 115 2011 23192 23197
14. T. Kim, S. Lim, K. Kwon, S.-H. Hong, W. Qiao, and C.K. Rhee et al. Electrochemical capacitances of well-defined carbon surfaces Langmuir 22 2006 9086 9088
15. W. Yuan, Y. Zhou, Y. Li, C. Li, H. Peng, and J. Zhang et al. The edge- and basal-plane-specific electrochemistry of a single-layer graphene sheet Sci Rep 3 2248 2013 1 7
16. E. Frackwiak, and F. Béguin Carbon materials for the electrochemical storage of energy in capacitors Carbon 39 2001 937 950
17. C. Zhao, P. Liu, Y. Jiang, D. Pan, H. Tao, and J. Song et al. Supercapacitor performance of thermally reduced graphene oxide J Power Sources 198 2012 423 427
18. V.A. Tur, A.V. Okotrub, M.M. Shmakov, E.O. Fedorovskaya, I.P. Asanov, and L.G. Bulusheva Functional composition and supercapacitor properties of graphite oxide reduced with hot sulfuric acid Phys Status Solidi B 250 2013 2747 2752
19. Y.J. Oh, J.J. Yoo, Y.I. Kim, J.K. Yoon, H.N. Yoon, and J.-H. Kim et al. Oxygen functional groups and electrochemical capacitive behavior of incompletely reduced graphene oxides as a thin-film electrode of supercapacitor Electrochem Acta 116 2014 118 128
20. B.-S. Shen, W.-F. Feng, J.-W. Lang, R.-T. Wang, Z.-X. Tai, and X.-B. Yan Nitric acid modification of graphene nanosheets prepared by arc-discharge method and their enhanced electrochemical properties Acta Phys-Chim Sin 28 2012 1726 1732
21. E. Widenkvist, D.W. Boukhvalov, S. Rubino, S. Akhtar, J. Lu, and R.A. Quinlan et al. Mild sonochemical exfoliation of bromine-intercalated graphite: a new route towards graphene J Phys D Appl Phys 42 2009 112003
22. K.A. Worsley, P. Ramesh, S.K. Mandal, S. Niyogi, M.E. Itkis, and R.C. Haddon Soluble graphene derived from graphite fluoride Chem Phys Lett 445 2007 51 56
23. R. Zboril, F. Karlichy, A.B. Bourlinos, T.A. Steriotis, A.K. Stubos, and V. Georgakilas et al. Graphene fluoride: a stable stoichiometric graphene derivative and its chemical conversion to graphene Small 6 2010 2885 2891
24. V.G. Makotchenko, E.D. Grayfer, A.S. Nazarov, S.-J. Kim, and V.E. Fedorov The synthesis and properties of highly exfoliated graphites from fluorinated graphite intercalation compounds Carbon 49 2011 3233 3241
25. F. Karlický, K.K.R. Datta, M. Otyepka, and R. Zbořil Halogenated graphenes: rapidly growing family of graphene derivatives ACS Nano 7 2013 6434 6464
26. J.T. Robinson, J.S. Burgess, C.E. Junkermeier, S.C. Badescu, T.L. Reinecke, and F.K. Perkins et al. Properties of fluorinated graphene films Nano Lett 10 2010 3001 3005
27. Z. Wang, J. Wang, Z. Li, P. Gong, X. Liu, and L. Zhang et al. Synthesis of fluorinated graphene with tunable degree of fluorination Carbon 30 2012 5403 5410
28. K. Guérin, M. Dubois, A. Houdayer, and A. Hamwi Applicative performances of fluorinated carbons through fluorination routes: a review J Fluorine Chem 134 2012 11 17
29. P. Barpanda, G. Fanchini, and G.G. Amatucci Structure, surface morphology and electrochemical properties of brominated activated carbons Carbon 49 2011 2538 2548
30. P. Meduri, H. Chen, J. Xiao, J.J. Martinez, T. Carlson, and J.-G. Zhang et al. Tunable electrochemical properties of fluorinated graphene J Mater Chem A 1 2013 7866 7869
31. n exhibit improved heterogeneous electron-transfer rates with increasing level of fluorination: towards the sensing of biomolecules Chem Eur J 20 2014 1 8
32. 2F revealed with angle-resolved X-ray absorption spectroscopy ACS Nano 7 2013 65 74
33. H.L. Poh, F. Šaněk, A. Ambrosi, G. Zhao, Z. Sofer, and M. Pumera Graphites prepared by Staudenmaier, Hofmann and Hummers methods with consequent thermal exfoliation exhibit very different electrochemical properties Nanoscale 4 2012 3515 3522
34. W. Rudorff Uber die lösung von brom im kristallgitter des graphits, bromgraphit Z Anorg Allg Chem 245 1941 383 390
35. M.S. Dresselhaus, and G. Dresselhaus Intercalation compounds of graphite Adv Phys 51 2002 1 186
36. A.S. Nazarov, V.G. Makotchenko, and V.E. Fedorov Preparation of low-temperature graphite fluorides through decomposition of fluorinated-graphite intercalation compounds Inorg Mater 42 2006 1260 1264
37. A.C. Ferrari Raman spectroscopy of graphene and graphite: disorder electron-phonon coupling, doping and nonadiabatic effects Solid State Commun 143 2007 47 57
38. A. Gupta, G. Chen, P. Joshi, S. Tadigadapa, and P.C. Eklund Raman scattering from high-frequency phonons in supported n-graphene layer films Nano Lett 6 2006 2667 2673
39. M.S. Dresselhaus, A. Jorio, M. Hofmann, G. Dresselhaus, and R. Saito Perspectives on carbon nanotubes and graphene Raman spectroscopy Nano Lett 10 2010 751 758
40. P.C. Eklund, N. Kambe, G. Dresselhaus, and M.S. Dresselhaus In-plane intercalate lattice modes in graphite-bromine using Raman spectroscopy Phys Rev B 18 1978 7069 7079
41. I.P. Asanov, L.G. Bulusheva, M. Dubois, N.F. Yudanov, A.V. Alexeev, and T.L. Makarova et al. Graphene nanochains and nanoislands in the layers of room-temperature fluorinated graphite Carbon 59 2013 518 529
42. A. Eckmann, A. Felten, A. Mishchenko, L. Britnell, R. Krupke, and K.S. Novoselov et al. Probing the nature of defects in graphene by Raman spectroscopy Nano Lett 12 2012 3925 3930
43. M.A. Pimenta, G. Dresselhaus, M.S. Dresselhaus, L.C. Cançado, A. Jorio, and R. Sairo Studying disorder in graphite-based systems by Raman spectroscopy Phys Chem Chem Phys 9 2007 1276 1291
44. A.C. Ferrari, J.C. Meyer, V. Scardaci, M. Lazzeri, F. Mauri, and S. Piscanec et al. Raman spectrum of graphene and graphene layers Phys Rev Lett 97 2006 187401
45. T. Ungár, J. Gubicza, G. Ribárik, C. Pantea, and T.W. Zerda Microstructure of carbon blacks determined by X-ray diffraction profile analysis Carbon 40 2002 929 937
46. L.G. Bulusheva, A.V. Okotrub, E. Flahaut, I.P. Asanov, P.N. Gevko, and V.O. Koroteev et al. Bromination of double-walled carbon nanotubes Chem Mater 24 2012 2708 2715
47. A. Yaya, C.P. Ewels, I. Suarez-Martinez, Ph. Wagner, S. Lefrant, and A. Okotrub et al. Bromination of graphene and graphite Phys Rev B 83 2011 0455411
48. E. Papirer, R. Lacroix, J.-B. Donnet, G. Nanse, and P. Fioux XPS study of the halogenation of carbon black - part 1. Bromination Carbon 32 1994 1341 1358
49. G. Nansé, E. Papirer, P. Fioux, F. Moguet, and A. Tressaud Fluorination of carbon black: an X-ray photoelectron spectroscopy study: I. a literature review of XPS studies of fluorinated carbons. XPS investigation of some reference compounds Carbon 35 1997 175 194
50. E.A. Aseeva, D.V. Pinakov, I.M. Oglezneva, G.N. Chekhova, L.N. Mazalov, and YuV Shubin X-ray photoelectron spectroscopy study of intercalated compounds of fluorinated graphite C2FxBr 0.01·yCH3CN J Struct Chem 5 2006 930 938
51. A. Vyalikh, L.G. Bulusheva, G.N. Chekhova, D.V. Pinakov, A.V. Okotrub, and U. Scheler Fluorine patterning in room-temperature fluorinated graphite determined by solid-state NMR and DFT J Phys Chem C 117 2013 7940 7948
52. Y. Sato, K. Itoh, R. Hagiwara, T. Fukunafa, and Y. Ito On the so-called "semi-ionic" C-F bond character in fluorine-GIC Carbon 42 2004 3243 3249
53. A. Becke Density-functional thermochemistry III. The role of exact exchange J Chem Phys 98 1993 5648 5652
54. C. Lee, W. Yang, and R.G. Parr Development of the Colle-Solvetti correlation-energy formula into a functional of the electron density Phys Rev B 37 1988 785 789
55. Jaguar, version 7.8. New York: Schrödinger, LLC; 2011.
56. C.D. Zangmeister Preparation and evaluation of graphite oxide reduced at 220 °C Chem Mater 22 2010 5625 5629
57. C. Bosch-Navarro, E. Coronado, C. Martí-Gastaldo, J.F. Sánchez-Royo, and M.G. Gómez Influence of the pH on the synthesis of reduced graphene oxide under hydrothermal conditions Nanoscale 4 2012 3977 3982
58. C.-M. Chen, Q. Zhang, M.-G. Yang, C.-H. Huang, Y.-G. Yang, and M.Z. Wang Structural evolution during annealing of thermally reduced graphene nanosheets for application in supercapacitors Carbon 50 2012 3572 3584
59. Y. Chen, X. Zhang, D. Zhang, P. Yu, and Y. Ma High performance supercapacitors based on reduced graphene oxide in aqueous and ionic liquid electrolytes Carbon 49 2011 573 580
60. Z. Fan, Q. Zhao, T. Li, J. Yan, Y. Ren, and J. Feng et al. Easy synthesis of porous graphene nanosheets and their use in supercapacitors Carbon 50 2012 1699 1712
61. P. Khanra, T. Kuila, S.H. Bae, N.H. Kim, and J.H. Lee Electrochemically exfoliated graphene using 9-anthracene carboxylic acid for supercapacitor application J Mater Chem 22 2012 24403 24410
62. D. Zhang, X. Zhang, Y. Chen, C. Wang, and Y. Na An environment-friendly route to synthesize reduced graphene oxide as a supercapacitor electrode material Electrochem Acta 69 2012 364 370
63. J. Yan, J. Liu, Z. Fan, T. Wei, and L. Zhang High-performance supercapacitor electrodes based on highly corrugated graphene sheets Carbon 50 2012 2179 2188
64. D.R. Dreyer, S. Murali, Y. Zhu, R.S. Ruoff, and W. Bielawski Reduction of graphite oxide using alcohols J Mater Chem 21 2011 3443 3447